Chromosomal transfer promoted by the promiscuous plasmid RP4.

We have studied the properties of the recombinant plasmid RP4λatt. This plasmid possesses the EcoRI-generated fragment of phage λ containing the genes att-int-xis (srIλ2–3) inserted into the single EcoRI site of the promiscuous plasmid RP4. The insertion of this λ fragment has no detectable effect on normal plasmid functions. However, it confers the ability to promote low-frequency polarized chromosomal transfer by int-promoted integration into the host λ attachment site attλ. We have succeeded in isolating an Hfr derivative which has the plasmid stably integrated at attλ. The Hfr derivative is unusual in having both an integrated and an autonomous RP4λatt stably coexisting in the same cell.     

Effect of plasmid F'Col+trp+ on the transfer of plasmid RP4]

Interaction of conjugative plasmids F'colV colB trp and PR4 in Escherichia coli host was studied during the transfer of the plasmids from cell to cell. The plasmid F'colV colB trp is found to stimulate the transfer of RP4 from the diplasmid strain. This seems to be due to stabilization of the conjugating pairs which require normal pili coded by the plasmid F'colV colB trp.     

Two mechanisms necessary for the stable inheritance of plasmid RP4

Plasmid RP4 is stably maintained in strains of Escherichia coli and other Gram-negative bacteria. Inactivation of the plasmid primase gene (pri) or removal of the PstIC fragment gave RP4 derivatives that are slightly unstably maintained in E. coli. Removal of the Tn 1 multimer resolution system (res and tnpR) did not lead to any detectable plasmid loss. Removal of all three of these regions, however, gave rise to pNJ5000 which is lost at high frequency. We have dissected the mechanisms causing this phenomenon. In contrast to RP4, pNJ5000 accumulates significantly as plasmid multimers in a Rec+ host; in a recA host, multimers are not seen and the plasmid is stably maintained. Multimers therefore appear to form by recA-mediated homologous recombination and cause plasmid instability, perhaps by interfering with partition. We demonstrate a mechanism provided by the PstIC fragment which acts on multimers analogously to the Tn1/3 resolution system on plasmid cointegrates, being effective only when cloned in cis. The loss of pri, on the other hand, can be complemented in trans. Our results are consistent with the view that primase prevents multimers forming (rather than resolving them once formed), perhaps by binding specifically to single-stranded regions of the plasmid and preventing homologous pairing.     

Mapping and cloning of the par-region of broad-host-range plasmid RP4

Various deletion mutants of the identical broad-host-range plasmids RP4 and RK2, obtained after conjugative transfer of these plasmids from Escherichia coli to Alcaligenes eutrophus H16, were tested with respect to their segregation behaviour. Although the parent plasmids and some of the deletion mutants were completely stable in both A. eutrophus and E. coli, other derivatives were lost under non-selective conditions. The analysis of these deletion mutants allowed the identification and mapping of a region encoding a partitioning system (par) between the tra2 region and the kanamycin resistance gene of RP4 (RK2). This area corresponds to the PstI-C restriction fragment of RP4 (RK2). Cloning of this fragment into several unstable vector plasmids including pBR322 and pACYC177 resulted in all cases in an increase of segregational stability. By insertion of the par-region into an unstable broad-host-range mobilizable plasmid and transfer to a series of gram-negative bacteria, it could be shown that the cloned par-region of RP4 is functional in a broad-host-range.     

Mapping of RP4 plasmid using deletion mutants of pAS8 hybrid (RP4-ColE1)

Summary We used the hybrid plasmid pAS8 in order to conduct the genetic analysis of RP4 plasmid. The presence of two replicons in the hybrid plasmid permitted to expand the spectrum of deletion mutants of RP4 isolated, which are capable to autonomous replication. The shortening of the hybrid plasmid was achieved by P22 transduction, by induction of deletion mutants using mitomycin C, as well as by selection of Tra^- mutants on the basis of resistance of cells to P-specific phages. These techniques have lead to isolation of clones possessing different combinations of plasmid resistance determinants.Comparison of phenotypic characteristics of deletion plasmids pAS9, pAS10, pAS11, pAS12 and pAS10-2 permitted to propose the map for pAS8 plasmid with the following sequence of markers: trakan-ColE1-amp-tet...Heteroduplex analysis of deletion mutants of pAS8 permitted to construct a physical map and to elaborate in greater detail the functional map of RP4 plasmid. The correlation between the ability of mutants to replicate in polA (TS) strain at nonpermissive conditions and the length of the deleted segment permitted to map rep genes of RP4 on a region with coordinates 9.8–17.3 kb. A relationship between the manifestation of incompatibility of mutants with Inc P-1 plasmids and the length of deletions points out that inc genes are located on DNA region with coordinates 2.1–9.8 kb. The analysis of replication of deletion mutants and the manifestation of incompatibility just as of the data about the size of appropriate deletions permitted to make the conclusion about the functional and genetic independence of the replication control and incompatibility control in RP4 plasmid.     

Transfer of prophage Mu into methylotrophic bacteria in the plasmid RP4

Bacteriophage Mu genome has been transferred into the cells of Pseudomonas methanolica and Methylobacterium sp. SKF240, that are naturally resistant to the bacteriophage, as a fragment of a hybrid plasmid RP4::Mu cts62. Temperature induction of the bacteriophage results in host cell lysis. Plasmid RP::Mu cis62 is maintained in methylotrophic cells presenting a cointegrative structure.The genetic and electrophoretic, analyses of the DNA isolated from transconjugant cells have confirmed the conclusion. Bacteriophage Mu propagation has been shown to be restricted in methylotrophic cells.     

RNA polymerase binding sites on the broad host range plasmid RP4

Binding sites of Escherichia coli RNA polymerase on RP4 plasmid DNA were determined electron microscopically. Comparison of the RNA polymerase binding map and the genetic map of RP4 revealed several strong binding sites outside the well-known RP4 genes. RNA polymerase binding sites for the three antibiotic resistance genes were also detected. Two binding sites were observed for the tra-1 region, whereas the tra-2 and tra-3 regions showed no prominent affinity for RNA polymerase. The genomic regions for the replication origins, oriV (for vegetative replication) and oriT (for transfer replication, equivalent to rlx), both exhibited strong binding to RNA polymerase, as did genomic regions which code for trans-acting replication functions (trfA and trfB).     

Detection of plasmid RP4 transfer in soil and rhizosphere,and the occurrence of homology to RP4 in soil bacteria

Plasmid RP4 transfer between introduced pseudomonads was studied in non-rhizosphere and rhizosphere soil. The addition of nutrients to the non-rhizosphere soil stimulated plasmid transfers between introduced donor and recipient cells, and no transfer was detected in nonamended soil. Transfer was also detected in soil in a model rhizosphere, but not in corresponding non-rhizosphere soil. Colony hybridization with whole plasmid RP4 DNA as a probe was employed to detect transfers to indigenous organisms in soil. Although transfers to introduced recipient cells were easily detected in parallel controls, no indigenous organisms were identified that had received RP4. Background levels of soil organisms with the RP4 resistance pattern were considerable, and about 10% of these populations contained DNA sequences with homology to RP4. However, no plasmids could be detected in any of 20 isolates, nor was resistance transfer to aPseudomonas fluorescens recipient detected in filter matings.     

Decreased symbiotic effectiveness of Rhizobium leguminosarum strains carrying plasmid RP4

The presence of derivatives of the broad host range plasmid RP4 in strains of Rhizobium leguminosarum biovar viciae severely inhibited nitrogen fixation by these strains in nodules on cultivars of pea (Pisum sativum). The strains formed small white nodules. Yield and total nitrogen values were comparable with those obtained for plants inoculated with a non-nodulating mutant. Strains carrying the same derivatives gave rise to nitrogen fixing nodules when inoculated on cultivars of lentils (Lens culinaris). Similar results were observed with plasmid R702 but not with R751, suggesting that the effect is limited to plasmids of the IncPα classification. Histological examination of nodules induced by strains carrying RP4 indicated that there are fewer infected cells and starch granules are organised unusually in the infected cells. Tn5 mutagenesis of plasmid RP4-4 was undertaken and Tn5 inserts were screened for abolition of the effect on nitrogen fixation. Eight mutants, having no effect on nitrogen fixation, were isolated. Seven of these had lost the ability to transfer by conjugation and the eighth was greatly reduced in conjugation frequency. Physical analysis of the transposon inserts revealed that they were located in the Tra regions of RP4.     

Transfer of plasmid RP4 in the spermosphere and rhizosphere of barley seedling

Transfer of plasmid RP4 to indigenous bacteria in bulk soil could only be detected in soil with nutrient amendment. Lack of physiological active donor and recipient cells was apparently one of the limiting factors in un-amended bulk soil. Plasmid transfer was detected both in the spermosphere and rhizosphere of barley seedlings. Transfer occured from seed coated donor bacteria (i) to introduced recipient bacteria and (ii) to indigenous bacteria present in soil. Plasmid transfer was also detected from donor bacteria introduced to the soil to seed coated recipient bacteria. Transfer efficiencies in the rhizosphere were significantly below the transfer efficiencies obtained in the spermosphere. The transfer efficiencies detected in the barley spermosphere were among the highest reported from any natural environment.     

In vitro insertion of the lambda attachment site into the plasmid RP4.

Summary The region of the phage lambda chromosome containing the attachment site (P · P) and the genes int and xis, excised by the action of endonuclease R.EcoRI, has been inserted into the unique site for that enzyme on the promiscuous conjugative plasmid, RP4, generating the recombinant plasmid RP4att. Transformants containing the hybrid plasmid were recognised by their ability to allow efficient lysogenization by phage b2 (Weil and Signer, 1968; Echols et al., 1968) containing the mutant attachment site · P. The construction and properties of the hybrid plasmid RP4att are described.     

Map of plasmid RP4 derived by insertion of transposon C.

We have determined the location of 36 sites on plasmid RP4 into which transposon C (an 8.5 × 10⁶ molecular weight DNA sequence conferring trimethoprim and streptomycin resistance) had spontaneously inserted itself. These were located by sucrose gradient analysis of EcoRI-generated and then, separately, the HindIII-generated DNA fragments from each RP4-TnC² plasmid. RP4 has a single EcoRI-susceptible site and, suitably displaced from this, a HindIII-susceptible site, whereas TnC has, respectively, one and two sites for these two enzymes. Thus the sizes of the restriction fragments depend on the location and orientation of the inserted TnC.Some of the RP4-TnC clones had lost one of the RP4 characters: transferability (Tra), tetracycline (Tc) or kanamycin (Km) resistances, but no ampicillin (Ap) sensitive clones were detected. Insertions giving each of these phenotypic changes cluster together at positions on the circular RP4 map that presumably locate the genes responsible for the Tra⁺, Km^r and Tc^r phenotypes. The Tra^? plasmids were grouped into four classes on the basis of their conferred phage sensitivities and plasmid copy numbers. The gene giving Ap^r was located by its known proximity to a BamHI-susceptible site. All the plasmids analysed had TnC inserted with one particular orientation. TnC insertions giving no detectable phenotypic change were not randomly placed around RP4, but clustered into certain regions. Two large regions, one containing TnA, had no TnC insertions. Ligation experiments with restriction fragments from various RP4-TnC plasmids led to the conclusion that both these regions contain genes essential to the replication and maintenance of RP4. The location of the HindIII site of RP4 within the gene giving Km^r should prove valuable to the use of this plasmid as a cloning vehicle.     

Fertility inhibition in Rhizobium lupini by the resistance plasmid RP4

Summary R plasmid RP4 inhibits the fertility of R. lupini. An RP4 carrying R. lupini donor strain is no longer capable of transferring chromosomal genes. After loss of RP4 the R. lupini fertility reappears. Plasmid RP4 spontaneously mutates at high frequency in R. lupini. RP4 mutants which do not inhibit fertility were isolated. These mutants were always transfer-defective, too. It is postulated that the genetic information for fertility inhibition in R. lupini is a substantial part of the transfer unit of the RP4 plasmid.     

Mechanism of integration of the broad-host-range plasmid RP4 into the chromosome of Myxococcus xanthus

The site-specific recombination mechanism through which the plasmid RP4 has been previously shown to integrate into the chromosome of Myxococcus xanthus has been investigated further. Once integrated in one of the numerous chromosomal sites from two different strains, through a precise site on the plasmid, the latter can be excised either precisely or after a definite 14.5-kb deletion. In some cases, the integration is followed by different DNA rearrangements that yield a higher rate of excision and integration. A model for the site-specific integration and excision of the plasmid is proposed.